JP2006078163A - Flat tube, plate body for manufacturing flat tube, and heat exchanger - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a flat tube capable of protecting at least one of side walls. <P>SOLUTION: A flat tube 1 comprises a pair of upper and lower walls 2 and 3 opposed to each other, two side walls 4 and 5 interconnecting the upper and lower walls 2 and 3 at left and right opposite side edges thereof, and a covering wall 6 provided over the outer surface of the left side wall 4 and brazed to the left side wall 4. The left side wall 4 is made from a side wall forming portion 9 projecting downward from the upper wall 2 integrally therewith and a side wall forming portion 11 projecting upward from the lower wall 3 integrally therewith by brazing these portions 9, 11 as butted against each other. The covering wall 6 is made by folding a covering wall forming portion 12 formed by extending one side edge of the upper wall 2. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  This invention is used as a heat exchange pipe for a heat exchanger, such as a condenser for an air conditioner or a refrigerant circulation pipe for an evaporator, an oil circulation pipe for an automobile oil cooler, a water circulation pipe for an automobile radiator, a heating medium circulation pipe for a heater core, etc. The present invention relates to a flat tube, a flat tube manufacturing plate used for manufacturing a flat tube, and a heat exchanger using the flat tube.

  In this specification and claims, the term “aluminum” includes aluminum alloys in addition to pure aluminum.

  Recently, as a car air conditioner capacitor, for example, as shown in FIG. 4, a pair of headers (30) and (31) arranged in parallel with a space between each other, and both headers (30) and (31) are mutually connected. Between the adjacent flat tubes (32) and a plurality of aluminum refrigerant flow flat tubes (32) that are arranged in parallel and spaced at both ends and connected to both headers (30) and (31), respectively. An aluminum corrugated fin (33) brazed to both the flat tubes (32) and an inlet pipe (34) connected to the upper end of the peripheral wall of the first header (30), An outlet pipe (35) connected to the lower end of the peripheral wall of the second header (31), a first partition plate (36) provided in a position above the middle of the first header (30), a second A second partition plate (37) provided in a lower position in the middle of the header (31), and the number of flat tubes (32) disposed above the first partition plate (36) , The number of flat tubes (32) disposed between the first partition plate (36) and the second partition plate (37) and the number of flat tubes (32) disposed below the second partition plate (37) are as follows. Each of the passages is configured to be sequentially reduced from above, and the gas phase refrigerant flowing in from the inlet pipe (34) flows through the outlet pipe (35) until it flows out as a liquid phase in each condenser. A so-called multi-flow type capacitor that flows in a meandering manner in group units is widely used as an alternative to conventional serpentine type capacitors that can realize high performance, low pressure loss, and ultra compact size. Has been.

  The refrigerant circulation flat tube (32) of the capacitor is required not only to have excellent heat exchange efficiency but also to have pressure resistance because a high-pressure gas refrigerant is introduced therein. Moreover, in order to reduce the size of the capacitor, it is required that the tube wall of the flat tube is thin and the tube height is low.

  As a flat tube excellent in heat exchange efficiency used for the capacitor described above, one described in Patent Document 1 is known. The flat tube described in Patent Document 1 includes a pair of flat walls opposed to each other, both side walls straddling both side edges of both flat walls, and spans both flat walls between both side walls and extends in the longitudinal direction. And a plurality of reinforcing walls provided at predetermined intervals, and a plurality of parallel fluid passages therein.

  Such a flat tube is made of a single metal plate as a whole, and has two flat wall forming portions of the same width forming both flat walls, a connecting portion connecting the flat wall forming portions and forming one side wall. In the two flat wall forming portions, a side wall forming portion formed integrally with the side edge opposite to the connecting portion and forming the other side wall is formed integrally with the two flat wall forming portions, respectively. A flat tube manufacturing plate-like body having a reinforcing wall forming portion is bent into a hairpin shape at a connecting portion, and the ends of both side wall forming portions are brought into contact with each other and brazed to each other, and formed on one flat wall forming portion. The tip of the reinforcing wall forming portion and the tip of the reinforcing wall forming portion formed on the other flat wall forming portion are brought into contact with each other and brazed to each other. And the thickness of the side wall formed by mutually brazing two side wall formation parts is thinner than the thickness of the side wall which consists of a connection part.

However, when the flat tube described in Patent Document 1 is used for a capacitor as described above, if a flying stone hits a side wall formed of two side wall forming portions, the side wall may be damaged by the impact.
JP-A-6-281373

  An object of the present invention is to provide a flat tube and a flat tube manufacturing plate body that can solve the above-described problems and can protect at least one of the side walls.

  In order to achieve the above object, the present invention comprises the following aspects.

  1) A flat tube having a pair of flat walls facing each other and two side walls provided across both side edges of both flat walls, and at least one of both side edges of one of the flat walls A flat tube in which a covering wall that covers an outer surface of at least one of the side walls is integrally formed on one side edge.

  2) The flat tube according to 1), wherein the covering wall is formed by bending a covering wall forming portion provided by extending at least one side edge of any one of the flat walls.

  3) The flat tube according to 1) or 2), wherein the covering wall is joined to the outer surface of the side wall.

  4) The flattening according to any one of the above 1) to 3), wherein the thickness of one side wall is thinner than the thickness of the other side wall, and the thin side wall outer surface is covered with a covering wall. tube.

  5) The flat tube as described in 4) above, wherein the thin side walls are provided by joining the ends of the side wall forming portions integrally formed in a protruding shape to the side edges of both flat walls.

  6) The flat tube as described in 5) above, wherein the covering wall covers at least the joint portion between the tips of the side wall forming portions in the entire outer surface of the thin side wall.

  7) The flat tube as described in 5) above, wherein the covering wall covers the entire outer surface of the thin side wall.

  8) The flat tube according to any one of 4) to 7), wherein the thick side wall is formed integrally with both flat walls.

  9) The flat tube according to any one of the above 1) to 8), wherein a plurality of reinforcing walls extending in the length direction are provided between the both side walls and extend across the two flat walls and spaced from each other. .

  10) The flat tube as described in 9) above, wherein the reinforcing wall is provided by abutting and joining the ends of the reinforcing wall forming portions integrally formed in a raised shape on both flat walls.

11) A pair of flat walls facing each other and two side walls provided across both side edges of both flat walls are provided, and at least one side edge of both side edges of one of the flat walls is provided. A flat tube manufacturing plate for manufacturing a flat tube in which a covering wall covering the outer surface of the side wall is integrally formed,
The whole consists of a single metal plate, two flat wall forming parts, a connecting part that connects both flat wall forming parts together and forms one side wall, and a connecting part in both flat wall forming parts is opposite It was provided by extending the side edge on the side opposite to the connecting part in either one of the flat wall forming parts, and the side wall forming part provided so as to protrude from the flat wall forming part, respectively. A plate-like body for producing a flat tube comprising a covering wall forming portion.

  12) The plate-shaped body for producing a flat tube according to 11) above, wherein the thickness of the side wall forming portion is thinner than the height of the connecting portion.

  13) The width of the covering wall forming portion is equal to or less than the sum of the heights of the two side wall forming portions and greater than the height of the side wall forming portion of the flat wall forming portion provided with the covering wall forming portion. Or 12).

  14) The plate-like body for producing a flat tube according to the above 11) or 12), wherein the width of the covering wall forming portion is equal to the total height of the two side wall forming portions.

  15) The metal plate is formed by rolling an aluminum brazing sheet having a brazing filler metal layer on both sides, and the outer side surface and the covering of the side wall forming portion of the flat wall forming portion where the covering wall forming portion is not provided 15. The plate-like body for producing a flat tube according to any one of the above 11) to 14), wherein the entire surface excluding the front end surface of the wall forming portion is covered with a brazing material layer.

  16) The plate-like body for producing a flat tube according to any one of 11) to 15) above is bent into a hairpin shape on both sides of the connecting portion, and the end portions of the side wall forming portion are brought into contact with each other, forming a covering wall A flat tube characterized in that the outer surface of both side wall forming portions is covered by bending the portion, and the tip portions of both side wall forming portions and the outer surface of both side wall forming portions and the covering wall forming portion are brazed simultaneously. Method.

  17) A plurality of flat tubes described in any one of the above 1) to 10) are positioned in parallel at a distance from each other between a pair of headers arranged in parallel and spaced from each other. A heat exchanger in which both ends of all the flat tubes are connected to both headers, fins are arranged in the ventilation gap between adjacent flat tubes, and the fins are brazed to the flat tubes.

  18) A refrigeration cycle comprising a compressor, a condenser and an evaporator, wherein the condenser comprises the heat exchanger described in 17) above.

  19) A refrigeration cycle comprising a compressor, a condenser, and an evaporator, wherein the evaporator comprises the heat exchanger described in 17) above.

  20) A vehicle on which the refrigeration cycle described in 18) or 19) above is mounted as a car air conditioner.

  21) After the plate-like body for producing a flat tube according to any one of the above 11) to 15) is folded into a hairpin shape on both sides of the connecting portion and the front end portions of the side wall forming portions are butted together, a covering wall is formed. Forming a plurality of bent bodies by folding the portions and covering the outer surfaces of the side wall forming portions, and preparing a pair of headers and fins in which a plurality of bent body insertion holes are formed at intervals. A pair of headers are arranged at intervals, and a plurality of folded bodies and fins are alternately arranged, both ends of the folded body are inserted into the folded body insertion holes of the header, and both sides of the folded body The flat tube is manufactured by brazing the outer surface of the wall forming portions and both side wall forming portions and the covering wall forming portion, and at the same time, the flat tube and the header, and the flat tube and the fin are simultaneously brazed. Method of manufacturing a heat exchanger to.

  According to the flat tube of the above 1), the side wall can be protected by the covering wall, so that even when used in a heat exchanger such as a condenser, the side wall is prevented from being damaged due to an impact when a foreign object collides, Leakage of refrigerant etc. is prevented.

  According to the flat tube of 2), the covering wall can be formed relatively easily.

  According to the flat tube of 3), the side wall is effectively protected by the covering wall.

  In the case of the flat tube of 4) above, the strength of the thin side wall is lower than the strength of the thick side wall, and there is a possibility that the above-mentioned problems may appear remarkably, but even in this case, the thin side wall is covered. If it is covered with a wall, a thin-walled side wall can be protected.

  In the case of the flat tube of 5) above, there is a risk that the strength of the side wall where the tips of the side wall forming portions are joined may be insufficient, but even in this case, if the thin side wall is covered by the covering wall, The side wall can be protected.

  In the case of the flat tube of 6), the strength of the joint portion on the thin side wall may be insufficient, but even in this case, the joint portion can be protected by the covering wall. In addition, when the tips of the side wall forming portions are joined by brazing, the brazing length between the inside and outside of the cross section is shortened, so that corrosion occurs at the brazing material portion existing between the tips of the side wall forming portions. Although it tends to progress and corrosion resistance may be reduced, if this joint is covered with a covering wall and the covering wall is further joined to the side wall by brazing, for example, the brazing length between the inside and outside in the cross section is Longer and better corrosion resistance.

  In the case of the flat tube of the above 7), the effect of protecting the thin side wall by the covering wall is excellent.

  According to the flat tube manufacturing plate-like body of the above 11), after bending the hairpin shape on both sides of the connecting portion and abutting the end portions of the side wall forming portion, the covering wall forming portion is bent and the outer surface of the both side wall forming portion Then, the flat tubes of the above 1) to 8) can be manufactured relatively easily by joining the tip portions of the side wall forming portions and the outer surface of the side wall forming portions and the covering wall forming portion. .

  According to the flat tube manufacturing plate of 13) above, the flat tube of 6) can be manufactured.

  According to the flat tube manufacturing plate-like body of 14), the flat tube of 7) can be manufactured.

  According to the flat tube manufacturing plate-like body of 15) above, using the brazing filler metal layer of the aluminum brazing sheet, the tip portions of the side wall forming portions and the outer surfaces of the side wall forming portions and the covering wall forming portion are joined. can do.

  According to the flat tube manufacturing method of 16), the flat tubes of 1) to 8) can be manufactured relatively easily.

  Embodiments of the present invention will be described below with reference to the drawings. In the following description, the upper and lower sides and the left and right sides of FIGS.

  FIG. 1 shows a flat tube, FIG. 2 shows a part of the process of manufacturing a flat tube using a flat tube manufacturing plate, and FIG. 3 is an enlarged view of the main part of FIG. Show.

  In FIG. 1, the flat tube (1) is made of aluminum, and the upper and lower walls (2) and (3) (a pair of flat walls) facing each other and the left and right edges of the upper and lower walls (2) and (3). Between the left and right side walls (4) (5), and the covering wall (6) that is integrally formed on the left edge of the upper wall (2) and covers the entire outer surface of the left side wall (4) 4) In (5), it is composed of a plurality of reinforcing walls (7) extending over the upper and lower walls (2) and (3) and extending in the length direction and provided at a predetermined interval from each other. The fluid passage (8) is provided. Although not shown in the figure, all the reinforcing walls (7) are provided with a plurality of communication holes through which the adjacent fluid passages (8) pass so as to form a staggered arrangement as viewed from above. Yes.

  The left side wall (4) is a side wall forming part (9) integrally formed in a raised shape from the left edge of the upper wall (2), and a side wall integrally formed in a raised shape from the left edge of the lower wall (3). The forming portion (11) is formed by brazing the tips with each other being abutted against each other. The right side wall (5) is formed integrally with the upper and lower walls (2) and (3). The thickness of the left side wall (4) is thinner than the thickness of the right side wall (5).

  The covering wall (6) is bent along the outer surface of the left side wall (4) by bending the covering wall forming part (12) (see the chain line in FIG. 1) formed by extending the left edge of the upper wall (2) to the left. And is brazed to the entire outer surface of the left side wall (4), that is, both side wall forming portions (9) and (11).

  The reinforcing wall (7) includes a downward reinforcing wall forming portion (13) integrally formed in a raised shape below the upper wall (2), and an upward reinforcing wall integrally formed in a raised shape above the lower wall (3). The forming portion (14) is formed by brazing the tips with each other being brought into contact with each other.

  The flat tube (1) is manufactured as shown in FIG. 2 using the flat tube manufacturing plate (15).

  The flat tube manufacturing plate (15) is formed by rolling a single aluminum brazing sheet having a brazing filler metal layer on both sides, as shown in FIG. 2 (a). A flat upper wall forming portion (16) (flat wall forming portion) and a lower wall forming portion (17) (flat wall forming portion) having the same width and forming the upper and lower walls (2) and (3), and the upper and lower walls The connecting portions (18) for integrally connecting the forming portions (16) and (17) and forming the right side wall (5), and the connecting portions (18 in the upper wall forming portion (16) and the lower wall forming portion (17)) ) And a side wall forming portion (9) (11) that is integrally formed in a raised shape from the side edge opposite to the side edge and forms the left side wall (4), and a connecting portion (18) in the upper wall forming portion (16). Is the covering wall forming part (12) formed by extending the opposite side edge (right edge) outward (right) in the left-right direction, and the upper wall forming part (16) and lower wall forming part (17 ) At predetermined intervals in the left-right direction. A plurality of reinforcing wall forming parts (13) and (14) integrally formed in a ridge shape, and the reinforcing wall forming part (13) and the lower wall forming part (17) of the upper wall forming part (16). The reinforcing wall forming part (14) is in a position that is symmetrical with respect to the center line in the width direction.

  The vertical height of the connecting portion (18) is larger than the thickness of the upper and lower wall forming portions (16) and (17) and the thickness of the side wall forming portions (9) and (11). Further, the thickness of the side wall forming portions (9) and (11) is larger than the thickness of the reinforcing wall forming portions (13) and (14). The protruding heights of the side wall forming portions (9) and (11) are substantially half the width in the left-right direction of the connecting portion (18).

  The width in the left-right direction of the covering wall forming portion (12) is equal to the sum of the protruding heights of the two side wall forming portions (9) and (11). The thickness of the covering wall forming portion (12) is equal to the thickness of the upper wall forming portion (16).

  By rolling the aluminum brazing sheet clad with brazing material on both sides, an upper wall forming part (16), a lower wall forming part (17), a connecting part (18), a side wall forming part (9) ( 11) Since the covering wall forming part (12) and the reinforcing wall forming part (13) (14) are integrally molded, the outer side surface (left side) of the side wall forming part (11) of the lower wall forming part (17) Surface) and the entire surface excluding the front end surface (right end surface) of the covering wall forming portion (12) are covered with a brazing material layer. In other words, from the upper and lower surfaces of the upper wall forming portion (16) and the lower wall forming portion (17), the upper and lower surfaces of the connecting portion (18), and the upper and lower wall forming portions (16) and (17) of the connecting portion (18). Left and right side surfaces of the part protruding upward, side wall forming portions (9) and front end surfaces and left and right side surfaces of reinforcing wall forming portions (13) and (14), front end surfaces and right side surfaces of the side wall forming portions (11), and A brazing filler metal layer (19) is formed on both upper and lower surfaces of the covering wall forming portion (12), and on the left side surface of the side wall forming portion (11) of the lower wall forming portion (17) and the front end surface of the covering wall forming portion (12). A brazing filler metal layer is not formed (see FIG. 3).

  Then, the flat tube manufacturing plate (15) is sequentially bent on the left and right sides of the connecting portion (18) by roll forming (see Fig. 2 (b)), and finally folded into a hairpin shape to form both side walls. The tips of the portions (9) and (11) and the tips of the reinforcing wall forming portions (13) and (14) are brought into contact with each other (see FIG. 2 (c)). At this time, the right side wall (5) is formed by the connecting portion (18).

  Next, the covering wall forming portion (12) is bent (see FIG. 2 (d)), and a bent body (20) is obtained along the outer surface of the side wall forming portions (9) and (11) (FIG. 2 (e)). )reference).

  Thereafter, the folded body (20) is heated to a predetermined temperature, and the ends of both side wall forming portions (9) and (11) and the ends of both reinforcing wall forming portions (13) and (14) are used using the brazing material layer. The left wall (4) and the reinforcing wall (7) are formed by brazing each other, the upper wall (2) is formed by the upper wall forming part (16), and the lower wall (17) is formed by the lower wall forming part (17). 3) is formed respectively. Also, the covering wall (6) is formed by brazing the covering wall forming portion (12) to the left side wall (4) using the brazing material layer. In this way, the flat tube (1) is manufactured.

  When the flat tube (1) is used, for example, as a flat tube for refrigerant circulation of a capacitor shown in FIG. 4, the flat tube (1) may be manufactured simultaneously with the manufacture of the capacitor. That is, the capacitor is manufactured as follows. First, a plurality of bent bodies (20) are prepared, and a pair of aluminum headers (30) (31) having a plurality of bent body insertion holes and a plurality of aluminum corrugated fins (33) are prepared. Next, a pair of headers (30) and (31) are arranged at intervals, and as many folding bodies (20) and fins (33) as the folding body insertion holes are arranged alternately, the folding body (20) Are inserted into the bent body insertion holes of the headers (30) and (31). Thereafter, these are heated to a predetermined temperature, and both side wall forming portions (9), (11) and both reinforcing wall forming portions (13), (14) of the bent body (20) are brazed, and the covering wall forming portion (12) is brazed to the side wall forming portions (9) and (11) to produce the flat tube (1), and at the same time, the flat tube (1) and the headers (30) and (31) and the flat tube (1 ) And the corrugated fin (33) are simultaneously brazed using the brazing material layer of the flat tube manufacturing plate (15). In this way, a capacitor is manufactured.

  The heat exchanger provided with the flat tube (1) described above is used in a vehicle, for example, an automobile, in which a refrigeration cycle using a chlorofluorocarbon refrigerant and having a compressor, a condenser, and an evaporator is mounted as a car air conditioner. Used as a cycle capacitor. Moreover, it is used as an evaporator of the refrigeration cycle. Furthermore, it may be mounted on an automobile as an oil cooler or radiator provided with the above-described flat tube (1).

The above-described flat tube (1) uses a supercritical refrigerant such as a CO ₂ refrigerant, and combines the refrigerant that has come out of the compressor, the gas cooler, the evaporator, the decompressor, and the gas cooler, and the refrigerant that has come out of the evaporator. A supercritical refrigeration cycle having an intermediate heat exchanger for heat exchange may be used for a gas cooler or an evaporator in a vehicle mounted as a car air conditioner, for example, an automobile.

  In the above embodiment, the flat tube is formed from a plate-like body for manufacturing a flat tube made of one aluminum brazing sheet, but the present invention is not limited to this, and the present invention has a pair of flat tubes. A coated wall forming portion using an extruded profile comprising a wall, both side walls integral with both flat walls, a reinforcing wall integral with both flat walls, and a coated wall forming portion formed by extending one flat wall. A flat tube that is bent along the outer surface of one side wall is also included.

It is a cross-sectional view showing an embodiment of a flat tube according to the present invention. It is a figure which shows a part of process of the method of manufacturing a flat tube from the flat body for flat tube manufacture. It is sectional drawing which expands and shows the principal part of FIG.2 (e). It is a perspective view which shows the capacitor | condenser for car air conditioners.

Explanation of symbols

(1): Flat tube
(2) (3): Upper and lower walls (flat walls)
(4) (5): Left and right side walls
(6): Coated wall
(7): Reinforcement wall
(9) (11): Side wall forming part
(12): Covered wall forming part
(15): Metal plate for flat tube manufacturing
(16): Upper wall forming part (flat wall forming part)
(17): Lower wall forming part (flat wall forming part)
(18): Connection part
(20): Folded body
(30) (31): Header
(32): Refrigerant distribution pipe
(33): Corrugated fin

Claims (21)

A flat tube having a pair of flat walls facing each other and two side walls provided across both side edges of both flat walls, and at least one side of both side edges of one of the flat walls A flat tube in which a covering wall that covers an outer surface of at least one of the side walls is integrally formed at an edge. The flat tube according to claim 1, wherein the covering wall is formed by bending a covering wall forming portion provided by extending at least one side edge of any one of the flat walls. The flat tube according to claim 1 or 2, wherein the covering wall is joined to the outer surface of the side wall. The flat tube according to any one of claims 1 to 3, wherein a thickness of one side wall is thinner than a thickness of the other side wall, and an outer surface of the thin side wall is covered with a covering wall. 5. A flat tube according to claim 4, wherein the thin side walls are provided by joining the ends of the side wall forming portions integrally formed in a protruding shape to the side edges of both flat walls. The flat tube according to claim 5, wherein the covering wall covers at least a joint portion between the front end portions of the both side wall forming portions in the entire outer surface of the thin side wall. The flat tube according to claim 5, wherein the covering wall covers the entire outer surface of the thin side wall. The flat tube according to any one of claims 4 to 7, wherein a thick side wall is formed integrally with both flat walls. The flat tube according to any one of claims 1 to 8, wherein a plurality of reinforcing walls extending in the lengthwise direction are provided between the both side walls so as to extend over both flat walls and be spaced from each other. The flat tube according to claim 9, wherein the reinforcing walls are provided by joining the ends of the reinforcing wall forming portions integrally formed in a raised shape to both the flat walls so as to face each other. A pair of flat walls facing each other and two side walls provided across both side edges of both flat walls are provided, and the side walls are provided on at least one side edge of either side of one of the flat walls. A flat tube manufacturing plate for manufacturing a flat tube in which a covering wall covering the outer surface of the flat tube is integrally formed,
The whole consists of a single metal plate, two flat wall forming parts, a connecting part that connects both flat wall forming parts together and forms one side wall, and a connecting part in both flat wall forming parts is opposite It was provided by extending the side edge on the side opposite to the connecting part in either one of the flat wall forming parts, and the side wall forming part provided so as to protrude from the flat wall forming part, respectively. A plate-like body for producing a flat tube comprising a covering wall forming portion. The plate for manufacturing a flat tube according to claim 11, wherein the thickness of the side wall forming portion is thinner than the height of the connecting portion. The width of the covering wall forming portion is equal to or less than the sum of the heights of the two side wall forming portions and larger than the height of the side wall forming portion of the flat wall forming portion provided with the covering wall forming portion. 12. A plate for producing a flat tube according to 12. The plate-shaped body for manufacturing a flat tube according to claim 11 or 12, wherein the width of the covering wall forming portion is equal to the total height of the two side wall forming portions. The metal plate is formed by rolling an aluminum brazing sheet having a brazing filler metal layer on both sides, and the outer side surface of the side wall forming portion and the covering wall formation of the flat wall forming portion not provided with the covering wall forming portion The plate-like body for manufacturing a flat tube according to any one of claims 11 to 14, wherein the entire portion excluding the tip surface of the portion is covered with a brazing material layer. The flat tube manufacturing plate-like body according to any one of claims 11 to 15 is bent into a hairpin shape on both sides of the connecting portion to butt the end portions of the side wall forming portion, and the covering wall forming portion is bent. A method of manufacturing a flat tube, comprising: covering the outer surfaces of both side wall forming portions; and brazing the front end portions of both side wall forming portions and the outer surface of both side wall forming portions and the covering wall forming portion at the same time. A plurality of flat tubes according to any one of claims 1 to 10 are arranged in parallel with each other between a pair of headers arranged in parallel and spaced from each other. A heat exchanger in which both ends of the flat tube are connected to both headers, fins are arranged in the ventilation gap between adjacent flat tubes, and the fins are brazed to the flat tubes. A refrigeration cycle comprising a compressor, a condenser, and an evaporator, wherein the condenser comprises the heat exchanger according to claim 17. A refrigeration cycle comprising a compressor, a condenser, and an evaporator, wherein the evaporator comprises the heat exchanger according to claim 17. A vehicle in which the refrigeration cycle according to claim 18 or 19 is mounted as a car air conditioner. The plate-like body for manufacturing a flat tube according to any one of claims 11 to 15 is bent into a hairpin shape on both sides of the connecting portion, the ends of the side wall forming portions are butted together, and then the covering wall forming portion is bent. A plurality of bent bodies are formed by covering the outer surfaces of the side wall forming portions, and a pair of headers and fins in which a plurality of bent body insertion holes are formed at intervals are prepared. The plurality of bent bodies and fins are alternately arranged, both ends of the folded body are inserted into the bent body insertion holes of the header, and both side wall forming portions of the folded body are disposed. The flat tube is manufactured by brazing the outer surface of both and both side wall forming portions and the covering wall forming portion, and at the same time, the flat tube and the header, and the flat tube and the fin are simultaneously brazed. Method of manufacturing a heat exchanger according to claim.

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